Configuration management in a multisystem environment

ABSTRACT

Configuration setting management is facilitated by setting data in a multisystem environment. A system having a configuration setting, in a multisystem environment having a test system and a production system, may identify the type for the setting based on a type identifier. The system may maintain the setting based on the type. Maintaining the setting may include, for a first type, making a primary location for the setting the production system, where the setting is initialized and editable in the production system. Maintaining the setting may include, for a second type, making the setting independent between the test system and the production system, where the setting is not transferred between the two systems and is editable at each system. Maintaining the setting may include, for a third type, making a primary location for the setting the test system, where the setting is initialized and editable in the test system.

FIELD

The present disclosure generally relates to management of configurationsettings in multisystem environments. Particular implementations relateto an architecture for classifying configuration settings andmaintaining configuration settings across multiple systems based on suchclassification.

BACKGROUND

Software systems, such as cloud systems, are often designed to haveconfiguration settings that influence a system's behavior and allowadjustments to the system to suit different users' needs. Theseconfiguration settings may be set once in a system before the system ismade available for use. Configuration settings may need to be testedbefore they are used. Testing may be done in a different system beforethe setting is used in a user system. Increasingly, such settings alsoneed to be adapted during the lifetime/usage of the system, which canincrease the testing needed. However, some settings may change so oftenthat stringent testing before use is difficult or limiting. Othersettings may never change. Further, a complex cloud environment may leadto a complex set of configuration settings, each with a different levelof use, need for testing, importance, or rate of change. This increasein complexity leads to increased difficulty in maintenance activitiesfor the configuration settings during lifecycle support of the softwaresystem. Thus, there is room for improvement in management ofconfiguration settings.

SUMMARY

This Summary is provided to introduce a selection of concepts in asimplified form that are further described below in the DetailedDescription. This Summary is not intended to identify key features oressential features of the claimed subject matter, nor is it intended tobe used to limit the scope of the claimed subject matter.

Techniques and solutions are described for management of configurationsettings in a multisystem environment. According to one method, asystem, in a multisystem environment having at least a test system and aproduction system, each with a local copy of a configuration setting,may identify the type for the setting based on a type identifier for thesetting. The system may maintain the setting based on the type.Maintaining the setting may include, for a first type, making a primarylocation for the setting the production system, where the setting isinitialized and editable at the production system. Maintaining thesetting may include, for a second type, separating the setting betweenthe test system and the production system, such that the setting may notbe transferred or read between the two systems and the first local copyis editable at the test system and the second local copy is editable atthe production system. Maintaining the setting may include, for a thirdtype, making a primary location for the setting the test system, wherethe setting is initialized and editable in the test system.

According to another method, a receiving system may receive a request toedit a setting, the setting having a type identifier. The receivingsystem may determine a maintenance rule for settings associated with thetype identifier, where the maintenance rule determines how a valueassociated with the setting is maintained between a first system and asecond system. The maintenance rules may include, for a first type, toinitialize and maintain the setting in the second system. Themaintenance rules may include, for a second type, to initialize andmaintain the setting independently in both the first system and thesecond system. The maintenance rules may include, for a third type, toinitialize and maintain the setting in the first system. This rule mayfurther include not transferring the setting to the second system. Thereceiving system may allow or deny the request to edit the value of thesetting in accordance with the determined maintenance rule based on thedetermined type identifier for the setting and whether the receivingsystem is the first system or the second system under the rule.

In a further method, a system in a multisystem environment may receive arequest to change a setting. The system may obtain setting datadescribing the setting, which may include a primary location identifierfor identifying a primary system of the setting in the multisystemenvironment. The system may compare its identifier to the primarylocation identifier for the setting. If the system is the same as theprimary location for the setting, then the system may allow the settingto be changed in accordance with the received change request.

The present disclosure also includes computing systems and tangible,non-transitory computer readable storage media configured to carry out,or including instructions for carrying out, an above-described method.As described herein, a variety of other features and advantages can beincorporated into the technologies as desired.

The foregoing and other objects, features, and advantages of theinvention will become more apparent from the following detaileddescription, which proceeds with reference to the accompanying figures.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a schematic diagram depicting a multisystem environmenttransferring system information.

FIG. 1B is a schematic diagram depicting a multisystem environmenttransferring settings between systems.

FIG. 2A is a diagram illustrating settings with setting types.

FIG. 2B is a diagram illustrating settings with specific setting types.

FIG. 2C is a diagram illustrating settings with specific setting typesin an alternate configuration.

FIG. 3A is a flowchart illustrating the lifecycle of a primary systemproperty of Type A settings.

FIG. 3B is a flowchart illustrating the lifecycle of a primary systemproperty of Type B settings.

FIG. 3C is a flowchart illustrating the lifecycle of a primary systemproperty of Type C settings.

FIG. 3D is a flowchart illustrating the lifecycle of a primary systemproperty of Type D settings.

FIG. 3E is a flowchart illustrating the lifecycle of a primary systemproperty of Type E settings.

FIG. 4A is a flowchart illustrating a maintenance process of Type Asettings.

FIG. 4B is a flowchart illustrating a maintenance process of Type Bsettings.

FIG. 4C is a flowchart illustrating a maintenance process of Type Csettings.

FIG. 4D is a flowchart illustrating a maintenance process of Type Dsettings.

FIG. 4E is a flowchart illustrating a maintenance process of Type Esettings.

FIG. 5 is a schematic diagram depicting setting maintenance in amultisystem architecture.

FIG. 6A is a flowchart illustrating a process for configurationmanagement in a multisystem environment using setting type.

FIG. 6B is a flowchart illustrating an additional process forconfiguration management in a multisystem environment using settingtype.

FIG. 6C is a flowchart illustrating a process for configurationmanagement in a multisystem environment using primary location of thesetting.

FIG. 7 is a diagram of an example computing system in which describedembodiments can be implemented.

FIG. 8 is an example cloud computing environment that can be used inconjunction with the technologies described herein.

DETAILED DESCRIPTION Example 1—Overview

Configuration settings for software are valuable tools to allow softwareto be customized for a particular system or environment, or for a useror customer, without hard-coding the settings directly into thesoftware. Such configuration settings often need to be changed, but in acontrolled manner to ensure correct software functioning and stability.Further, the ability to make changes may need to be limited to certainindividuals, such as a system administrator or advanced user, or tocertain resources external to the software, such as a data provider.Monitoring the changes to configuration settings is also important forensuring correct software functioning and that any problems arising froma change can be corrected or the change undone.

Further, different instances of software may be implemented acrossdifferent systems in a multisystem environment, each instance having acopy of the configuration settings. Managing the configuration settingsbetween the different systems correctly can ensure more effective andtimely software deployment or greater software availability, whilelowering the cost of software maintenance. Thus, it can be important tohave an effective architecture for managing configuration settings forsoftware between systems.

The disclosed technologies facilitate configuration setting managementin a multisystem environment. This is accomplished through a set ofconfiguration setting types, into which a configuration setting may becategorized. Each type of configuration setting is programmaticallymanaged between systems according to specific rules for that type in thesystem architecture.

A variety of examples are provided herein to illustrate the disclosedtechnologies. The technologies from any example can be combined with thetechnologies described in any one or more of the other examples toachieve the scope and spirit of the disclosed technologies as embodiedin the claims, beyond the explicit descriptions provided herein.Further, the components described within the examples herein may becombined or recombined as well, as understood by one skilled in the art,to achieve the scope and spirit of the claims.

Example 2—Multisystem Environment

A multisystem environment with configuration settings is illustrated inFIG. 1A. A multisystem environment 100 may include a development system110, a quality control system 120, and a production system 130. Amultisystem environment 100 may include fewer systems or additionalsystems. Some or all of the systems in the multisystem environment maybe in a cloud environment 105. One or more of the systems in themultisystem environment 100 may have configurations settings. The devsystem 110 may have configuration settings 115; the quality system 120may have configuration settings 125; the production system 130 may haveconfiguration settings 135. Although the present disclosure generallyproceeds with reference to two or more of a development system 110, aquality control system 120, and a production system 130, it should beappreciated that these labels are by way of example and for convenientpresentation and that the systems in the multisystem environment 100 caninclude other types of systems which can be, more generally, first,second, third, etc., systems.

A system generally runs software or a set of software, which isgenerally accessible to a user, a customer, or an external system. Asystem may also run data storage, such as a database, or other featuresuseful to execution of software. The configuration settings aregenerally used to control or customize the software on the system. Asystem may be a discrete computer, a set of networked computers, or alogical system on one or more computers (such as a partition).

The systems in a multisystem environment may be copies of each other,running separate instances of the same software. The configurationsettings are generally used to configure the software to run correctlyon the separate systems. The systems may be used as different versionsof each other, each serving a different purpose, or as separate systemsbut otherwise the same. The development system 110 may be used forsoftware development, allowing developers to run and test software. Thesoftware may then be transferred to the quality control system 120,where testers may run the software and test its functionality.Thereafter, the software may then be transferred to the productionsystem 130, where it may be made widely available to users or customers.Generally, the development system 110 is for unstructured testing andcode writing, the quality control system 120 is for structured testing,including both verification and validation, and the production system130 is not used for testing and instead provides the current version ofthe software to end users.

Copying the software from one system to another system may beaccomplished in several ways. In some instances, the entire system maybe exported and placed on a different system. This could be donemanually or as a scheduled process managed by software. In anotherinstance, only a portion of the software or other features in a systemmay be exported to another system. This may be a formal process basedaround software versions and official releases, or it may be moreinformal based around, for example, testing needs (between testingsystems), minor changes, or urgent fixes.

In some scenarios, it may be desirable for configuration settings (orparticular properties thereof, such as whether a setting is editable ata particular system or which system services as a primary or home systemfor the setting) to be accessible between the systems, as illustrated inFIG. 1B. In such cases, one or more configuration settings may betransferred from one system to another system without transferring otherfeatures of the system. In some instances, a configuration setting maybe accessed from a different system to change the setting or acharacteristic of the setting, or to lock/unlock a setting. The methodsfor managing such setting interaction between systems is furtherdescribed herein.

Example 3—Settings

A system may have one or more configuration settings, also calledsettings. A setting may be a value or a variable used by the systemduring execution. Settings are generally consistent across the system,however, settings may vary within the system, or between differentsystems, based on a known factor or factors. For example, each user mayhave a separate set of settings, or each department of a customer mayhave separate settings. Settings may be modifiable by a user or users.In some scenarios, settings may only be changed by a technical user oradministrator, or, in some cases, a separate external resource.

A setting may be used for determining control flow or logic flow, suchas a threshold value for performing analysis. A setting may be used fordata calculations or analysis, similar to a global variable, such as aconstant value or conversion rate value. A setting may be used forsystem environment information, such as address or gateway informationfor an external resource or the number of attempts to make incommunication before reporting failure.

A setting may have further characteristics beyond its value. A settingmay be a particular type of setting; the type provides furtherinformation about the nature of the setting or how to use the settingbased on the definition of the type. The type may also define some orall of the other characteristics a setting has or the values of some orall of those other characteristics. A setting may have a primarylocation, which may be the primary system that maintains the setting ina multisystem environment. A setting may also have an indicator forallowing or disallowing modification of the setting's primary location.A setting may also have a read/write lock, indicating if the setting maybe read, or overwritten, both read and overwritten, or neither (forexample, is inaccessible by a particular user or system). A setting mayhave any combination of these characteristics, and/or othercharacteristics not disclosed herein.

Example 4—Setting Storage

Settings are typically stored on each system in a multisystemenvironment. The setting may be the same setting, but with a local copystored on some or all of the systems in a multisystem environment. Thesettings may be stored in a variety of ways that make them accessiblefor editing without restarting the software on the system. For example,the settings may be stored in a file, such as a text file. The settingsmay be stored in a registry, such as a system registry. The settings maybe stored in a database on the system or accessible by the system.

Settings generally are stored with a name or identifier and the value ofthe setting. Further characteristics of the setting are also stored withthe setting, such as a primary location of the setting. In oneembodiment, the setting and its characteristics may be stored in aregistry. A setting name may be stored as an identifier in the registryand other characteristics of the setting, such as the value, type,primary location, or editability indicator may be stored as subentriesin the registry under the identifier. Each characteristic is linked to acorresponding setting and may have an identifier, such as a name, and avalue.

In another scenario, a setting may be stored in a database. A settingmay be stored as a row in a settings table, with a value in a column fora particular row ID identifying the setting and further columnsproviding characteristics of the setting. For example, the furthercolumns may include the name of the setting, the value of the setting,the type of the setting, the primary location of the setting, or othercharacteristics associated with the setting. Further rows may storefurther settings, with their corresponding characteristics.

Example 5—Setting Types

A setting may be defined as having a type, as illustrated in FIG. 2A. Asetting 200 may be one type of setting from a set of types, such as Type1 201 through Type n 209. Any number of types (n) may be defined. Insome cases, settings may be implemented as data objects (e.g., instancesof a class or composite data type). In such a scenario, Type 1 201generalizes to Setting 200, as do all types through Type n 209. Thus, asetting of Type 1 201 will have all characteristics of Type 1 plus allcharacteristics of settings 200. For instance, setting 200 can representa base class and types through Type n 209 can be derived classes.

In another implementation, a setting may be classified into a type(e.g., a class can implement all types, and a data member or variablecan specify a type for a particular instance of the class). In thisscenario, setting 200 may be categorized as Type 1 201 or any other typethrough Type n 209. Generally, a setting will be of only one type;however, in some embodiments a setting may be of more than one type.

Each type defines certain characteristics of the setting. The type maydefine the nature of the setting, such as if it is an environmentalvariable or a data calculation value. In one embodiment, the typedefines how the setting is maintained, such as how it is managed betweendifferent systems in a multisystem environment, such as which systems,for example, may edit the setting or which system has primacy for thesetting. The type may further determine if the setting can betransferred between systems or under what circumstances it may betransferred.

Specific types of settings may be defined as illustrated in FIG. 2B. Asetting 200 may be of Type A 210, Type B 220, Type C 230, Type D 240, orType E 250. Each of these types may be defined by how they behavebetween different systems. This may include in which system informationspecifying a type for a particular setting may be maintained.Maintenance of a setting may include changing the value of a settingand/or testing a setting. In one embodiment, maintenance of a settingmay include read and write locks for the setting. In another embodiment,the type of setting may include information about the primary locationof the setting, also known as the source or origin, and informationindicating if the primary location may be changed for the setting. Thisinformation helps enable setting management across multiple systems byidentifying if a setting in a given system may be changed or under whatcircumstances it can be changed.

The types of settings may be interrelated, as illustrated in FIG. 2C. Asetting 200 may be of Type A 211, Type B 221, Type C 231, Type D 241, orType E 251, similar to FIG. 2B. However, different types may sharecharacteristics or functionality while still being separate types. TypeC 231 may generalize to Type B 221, which then generalizes to setting200. In this scenario, Type C 231 has its own characteristics andfunctionality, such as primary location and modifiability of the primarylocation, but also has the additional characteristics and functionalityas Type B 221. However, Type B 221 may not have any of thecharacteristics under Type C 231.

A type may be divided into different subtypes; Type E 251 may be dividedinto three subtypes 251 a, 251 b, 251 c. Each subtype 251 a, 251 b, 251c has the same characteristics as Type E 251, but each may includedifferent additional characteristics. For example, one subtype 251 a mayinclude no additional characteristics and so generalize to a setting200. Another subtype 251 b may generalize to Type B 221, and so have thecharacteristics of Type E and Type B. A third subtype 251 c maygeneralize to Type C 231, and so have the characteristics of Type E,Type C, and also Type B 221 through Type C.

Although the present disclosure generally referrers to types havinglabels A-E, it should be appreciate that such labels are used merely forconvenient presentation. That is, for example, properties of a Type Asetting 211 could instead be associated with a setting having a label ofType B, or another identified (e.g., any value that serves as anidentifier, such as a unique identifier, for the Type, including integeror string values).

Example 6—Primary Location of Settings

A setting may have a primary location, which may be based on thesetting's type. The primary location is the system in the multisystemenvironment where the setting is maintained. This is generally a singlesystem. Maintaining a setting may include changing or updating asetting, providing a copy of the setting to other systems, trackingchanges to a setting, or preventing unauthorized changes to a setting.Maintaining a setting may generally refer to a setting that alreadyexists, however, in some embodiments it may further include creating orinitializing a setting. Initializing a setting may include defining asetting, assigning a value to a setting, defining characteristics for asetting or assigning values to characteristics for a setting, orallocating storage for a setting, such as creating a registry entry forthe setting or an entry in a database table for the setting.

A setting's primary location may be the system where the setting can bechanged. It may also be the system that is considered to have thecurrent (or “true” or authoritative) value of the setting. For example,if an administrator or developer needed to know the current value of asetting (e.g. for use in software development, testing, or for use in aparticular system), the primary location of the setting indicates fromwhich system they should get the value, in case the values are differentin different systems.

In some implementations, the setting may only be changed at the primarylocation; changes in other systems are prevented. In otherimplementations, the setting may be changed in other systems, but thesechanges may not be transferred to or overwrite the setting in theprimary location. Further, these changes may also not be transferred toother systems in the multisystem environment. Also, in at least somecases, settings in systems that are not the primary location may beoverwritten by the setting from the primary system, if the setting istransferred. Thus, the primary location may be used to determine theprimary value and other characteristics of a setting between thedifferent systems in the multisystem environment.

In some scenarios, the primary location of a setting may be able to bechanged. For example, some types of settings may have their primarylocation change during their lifecycle, whereas other types of settingsmay not have their primary location change. The editability of theprimary location may be indicated by a flag or other characteristic ofthe setting, and/or may be determined by the setting's type. Changingthe primary location of a setting changes which system maintains (e.g.may change) the setting.

Example 7—Changing Setting Type

In some embodiments, the type of a setting may be changed. For example,a Type B setting may be changed to a Type C setting based on changes tothe software during the lifecycle of the software. Generally, such achange may be done and be effective at the primary location for thesetting, as determined by its current type. This is generally true forother characteristics of the setting as well. Once a setting's type hasbeen changed, that change may (and, in some cases, will) be transferredto other systems with the setting in the multisystem environment and thesetting will be treated as a setting of the new type.

In another embodiment, setting types may not be changed, or may only bechanged through revisions to the software. This may prevent mistakenlymanipulating a setting incorrectly (e.g. allowing changes at anincorrect system) by changing the setting type.

The ability to change a setting's type may be controlled by an indicatorcharacteristic of the setting, such as a flag, stored as acharacteristic of the setting. Further, the ability to change asetting's type may be limited to only certain users, such as a systemadministrator.

A setting type may also have subtypes. Subtypes may function similar toother setting types, eliminating the need to change the setting type.For example, Type E settings may have a subtype that behaves like Type Bor Type C. Subtypes may also be used to further delineate additionalcharacteristics of a setting type, without necessarily relating to othertypes. This may be useful when the additional characteristics only applyto a portion of settings within the type.

Example 8—Type A Settings

FIG. 3A illustrates the primary location characteristic 310 of Type Asettings. The primary location of a Type A setting 311 begins in aproduction system 302 and then ends in the production system. Thus, theprimary location is always the production 302 system for Type Asettings, and not a quality system 301 (or any other system in amultisystem environment). Further, the primary location does not changefor Type A settings, as shown by the Type A setting primary locationcharacteristic 310 beginning and ending under Production System 302without ever changing.

The quality system 301 may have a copy of the Type A setting 311,however, this copy is not maintained. As a Type A setting, if thequality system 301 has a copy of the Type A setting 311, that copyshould not be transferred to the production system 302. The qualitysystem's 301 copy, however, may come from the Type A setting 311 in theproduction system 302. Alternatively, the copy in the quality system 301may have a static value that is not pulled from the Type A setting 311in the production system 302. Such a copy in the quality system may beuseful or necessary to allow for testing of other features or settingsin the quality system.

FIG. 4A illustrates a maintenance process 410 for Type A settings. In aproduction system 402, a setting change may be initiated 411 for a TypeA setting. Initiating the setting change 411 may include detecting thatthe setting is a Type A setting. It may also include retrieving thecurrent value of the setting or prompting the user to provide a newvalue. This step 411 may further include ensuring the setting may bechanged at this moment, such as that there is no write lock on thesetting. Input is provided for the new value and the setting is changedto the new value at 412. The new value may come from user input, such asthrough a user interface, or from an external resource, such as adatabase, a batch update process, or a data feed from a data provider.

Type A settings are useful for values that may change frequently and socannot go through testing or manipulation on other systems. For example,currency exchange rates or tax code mappings change frequently, and somay be categorized as Type A settings.

Example 9—Type B Settings

FIG. 3B illustrates the primary location characteristic 320 of Type Bsettings. The primary location of a Type B setting 321 begins in thequality system 301 and then ends as Type B setting 322 in the productionsystem 302. Thus, the primary location for a Type B setting is first thequality system 301 and later changed to the production system 302. Oncea Type B setting's 321 primary location is changed to the setting 322 inthe production system 302, the primary location does not change again.In some embodiments, the primary location in this scenario may no longerbe editable.

FIG. 4B illustrates the maintenance process 420 for a Type B setting. Aprocess 420 a for changing a Type B setting may begin in the qualitysystem 401. In the quality system 401, a setting change may be initiated421 a for a Type B setting. Initiating the setting change 421 a mayinclude detecting that the setting is a Type B setting. It may alsoinclude retrieving the current value of the setting or prompting theuser to provide a new value. This step 421 a may further includeensuring the setting may be changed at this moment, such as confirmingthat there is no write lock on the setting.

The primary location of the setting may also be obtained as part ofinitiating the setting change 421 a. The primary location of the settingis then analyzed 422 a to determine which system (401, 402) is theprimary location. If the primary location is the production system 402,then the process 420 a stops and no change is made. If the primarylocation is the quality system 401, then the process 420 a proceeds,allowing the setting to be changed.

Input is provided for the new value and the setting is changed to thenew value at 423 a. The new value may come from user input, such asthrough a user interface, or from an external resource, such as adatabase, a batch update process, or a data feed from a data provider.The change to the setting may then be validated 424. Validation mayinclude testing the software with the new setting, such as manualtesting by a user or running testing scripts that simulate use of thesoftware. Validating the change 424 may further include analyzing theresults of the test to determine if the outcomes match those desired.

After validation, a determination 425 is made to export to the settingto another system. If the setting is not ready for export, such as thechanges to the setting do not have the desired effect, then furtherchanges may be made to the setting 423 a. If the setting is functioningcorrectly, the setting may be exported 426 to the production system 402.Exporting the setting 426 may include immediately sending the setting tothe production system 402 or writing the setting to a transfer file fortransfer at a later time to the production system. The setting isreceived 427 by the production system 402 and stored. The setting isthen checked-in 428, which includes changing the primary location of thesetting from the quality system 401 to the production system 402.

Independent from the process 420 a in the quality system 401, a process420 b for changing a Type B setting may begin in the production system402. In the production system 402, a setting change may be initiated 421b for a Type B setting. Initiating the setting change 421 b may includedetecting that the setting is a Type B setting. It may also includeretrieving the current value of the setting or prompting the user toprovide a new value. This step 421 b may further include ensuring thesetting may be changed at this moment, such as confirming that there isno write lock on the setting.

The primary location of the setting may also be obtained as part ofinitiating the setting change 421 b. The primary location of the settingis then analyzed 422 b to determine which system (401, 402) is theprimary location. If the primary location is the quality system 401,then the process 420 b stops and no change is made. If the primarylocation is the production system 402, then the process 420 b proceeds,allowing the setting to be changed. Input is provided for the new valueand the setting is changed to the new value at 423 b. The new value maycome from user input, such as through a user interface, or from anexternal resource, such as a database, a batch update process, or a datafeed from a data provider.

Type B settings are useful for values that may change frequently butrequire some testing or fine-tuning before being moved to a productionenvironment. Additionally, Type B settings may be useful for settingsthat need testing before deployment, but will not change much oncedeployed. For example, planned order values, which define productrequisitions that will be automatically generated by a system, may becategorized as Type B settings.

Example 10—Type C Settings

FIG. 3C illustrates the primary location characteristic 330 of Type Csettings. The primary location of a Type C setting 331 begins in thequality system 301. Thereafter, the primary location changes to theproduction system 302 with the corresponding Type C setting 332. Theprimary location may then transfer between the setting 332 in theproduction system 302 and the setting 331 in the quality system 301.

In general, the primary location is changed from the quality system 301to the production system 302 when the setting is exported from thequality system to the production system. Thereafter, the primarylocation remains the production system 302 until the quality system 301requests control of the setting from the production system; this isgenerally done because a change to the setting requires testing beforebeing implemented in the production system. There is not a final primarylocation for a Type C setting, because Type C settings' primary locationmay transition between two systems in a multisystem environment. Theprimary location of a Type C setting is modifiable. The process forchanging the primary location of a Type C setting is further detailed inthe maintenance process 430 for a Type C setting.

FIG. 4B illustrates the maintenance process 430 for a Type C setting. Aprocess 430 a for changing a Type C setting may begin in the qualitysystem 401. In the quality system 401, a setting change may be initiated431 a for a Type C setting. Initiating the setting change 431 a mayinclude detecting that the setting is a Type C setting. It may alsoinclude retrieving the current value of the setting or prompting theuser to provide a new value. This step 431 a may further includeensuring the setting may be changed at this moment, such as confirmingthat there is no write lock on the setting.

The primary location of the setting may also be obtained as part ofinitiating the setting change 431 a. The primary location of the settingis analyzed 432 a to determine which system (401, 402) is the primarylocation. If the primary location is the quality system 401, then theprocess 430 a proceeds directly to changing the setting 434 a. If theprimary location is the production system 402, then the quality system401 requests to check-out 433 the setting from the production system.This may include changing the primary location of the setting from theproduction system 402 to the quality system 401.

Once the setting is checked-out from the production system 402 to thequality system 401, the setting may be changed in the quality system andnot changed in the production system. Input is provided for the newvalue and the setting is changed to the new value at 434 a. The newvalue may come from user input, such as through a user interface, orfrom an external resource, such as a database, a batch update process,or a data feed from a data provider.

The change to the setting may be validated 435. Validation may includetesting the software with the new setting, such as manual testing by auser or running testing scripts that simulate use of the software.Validating the change 435 may further include analyzing the results ofthe test to determine if the outcomes match those desired.

After validation, a determination is made 436 to export the setting tothe production system 402. If the setting is not ready for export, suchas the changes to the setting do not have the desired effect, thenfurther changes may be made to the setting 434 a. If the setting isready for export, such as the setting is functioning correctly, thesetting may be exported 437 to the production system 402. Exporting thesetting 437 may include immediately sending the setting to theproduction system 402 or writing the setting to a transfer file fortransfer at a later time to the production system. The setting isreceived 438 by the production system 402 and stored. The setting isthen checked-in 439, which includes changing the primary location of thesetting from the quality system 401 to the production system 402.

Independent from the process 430 a in the quality system 401, a process430 b for changing a Type C setting may begin in the production system402. In the production system 402, a setting change may be initiated 431b for a Type C setting. Initiating the setting change 431 b may includedetecting that the setting is a Type C setting. It may also includeretrieving the current value of the setting or prompting the user toprovide a new value. This step 431 b may further include ensuring thesetting may be changed at this moment, such as confirming that there isno write lock on the setting.

The primary location of the setting may also be obtained as part ofinitiating the setting change 431 b. The primary location of the settingis analyzed 432 b to determine which system (401, 402) is the primarylocation. If the primary location is the quality system 401, then theprocess 430 b stops and no change is made. If the primary location isthe production system 402, then the process 430 b proceeds, allowing thesetting to be changed. Input is provided for the new value and thesetting is changed to the new value at 434 b. The new value may comefrom user input, such as through a user interface, or from an externalresource, such as a database, a batch update process, or a data feedfrom a data provider.

Type C settings are useful for values that may change but may needtesting in the quality system 401, in some circumstance, before beingused in the production system 402. In other circumstances the change maynot need testing and can be made directly in the production system. Forexample, a balance sheet structure (e.g., a chart of accounts) orfinancial statement version (e.g. G/L accounts) may be defined forfinancial accounts and may vary by region, country, or business. Thebalance sheet definition or financial statement version may be a Type Csetting because changes to a balance sheet definition or financialstatement version may require extensive testing before being used inproduction as balance sheets or financial statements often have specificlegal requirements for their structure. Balance sheet definitions orfinancial statement versions may require testing when they are changedto accommodate new legal requirements, or they may require testing whena new country or region is added to the system with a new balance sheetdefinition or financial statement version.

In another example, a minor change to a Type C setting can be made toimprove the processing speed. If the setting change is not expected tohave significant side effects, it can be made directly in the productionsystem 402. In this case a change in the primary location of the Type-Csetting may be not required. Thus, Type C settings are useful becausethey can allow the primary location of the Type C setting to varydepending on particular needs, yet can facilitate keeping the qualitysystem 401 and the production system 402 synchronized, which previouslywas a cumbersome, error-prone manual processes of synchronizing thesystems.

Example 11—Type D Settings

FIG. 3D illustrates the primary location characteristic 340 of Type Dsettings. A Type D setting is maintained independently in each system ofa multisystem environment. A Type D setting 341 has a primary locationin the quality system 301 and, simultaneously, the Type D setting 342also has a primary location in the production system 302. The setting341 in the quality system 301 is the same setting as the setting 342 inthe production system 302, but each may have a different value(including, in some cases, having a value in one system and not yetbeing assigned a value in another system).

In one implementation, the primary location is both the quality system301 and the production system 302 at the same time. In anotherimplementation, no primary location may be indicated for the setting.The primary location is generally not modifiable for a Type D settingbecause each setting is maintained independently in each system.However, the primary location for a Type D setting may be modified toadd a new system in the multisystem environment, for example, if theprimary location lists all systems in which the setting is found (orremove a system if a system is dropped from the multisystemenvironment).

FIG. 4D illustrates the maintenance process 440 for a Type D setting. Aprocess 440 a for changing a Type D setting may begin in the qualitysystem 401. In the quality system 401, a setting change may be initiated441 a for a Type D setting. Initiating the setting change 441 a mayinclude detecting that the setting is a Type D setting. It may alsoinclude retrieving the current value of the setting or prompting theuser to provide a new value. This step 441 a may further includeensuring the setting may be changed at this moment, such as confirmingthat there is no write lock on the setting.

Input is provided for the new value and the setting is changed to thenew value at 442 a. The new value may come from user input, such asthrough a user interface, or from an external resource, such as adatabase, a batch update process, or a data feed from a data provider.

Independent from the process 440 a in the quality system 401, a process440 b for changing a Type D setting may begin in the production system402. In the production system 402, a setting change may be initiated 441b for a Type D setting. Initiating the setting change 441 b may includedetecting that the setting is a Type D setting. It may also includeretrieving the current value of the setting or prompting the user toprovide a new value. This step 441 b may further include ensuring thesetting may be changed at this moment, such as confirming that there isno write lock on the setting.

Input is provided for the new value and the setting is changed to thenew value at 442 b. The new value may come from user input, such asthrough a user interface, or from an external resource, such as adatabase, a batch update process, or a data feed from a data provider.

Type D settings are useful for values that generally will be differentin each system. For example, environmental variables, such as an addressfor an external resource, are often different from system to system, andso may be categorized as Type D settings. Another example are networkcredentials, which may be necessary to properly access certain externalsystems, but may be different from one system to another system in themultisystem environment.

Example 12—Type E Settings

FIG. 3E illustrates the primary location characteristic 350 of Type Esettings. Type E setting 351 may be divided into subtypes 351 a, 351 b,351 c (which can be referred to respectively as first, second, and thirdsubtypes). If Type E settings are not divided into subtypes, then Type Esettings functions as described for the first subtype 351 a. The primarylocation of the first subtype 351 a of the Type E setting 351 begins inthe quality system 301 and also ends in the quality system. Thus, theprimary location may always be the quality system 301 for the firstsubtype 351 a of the Type E setting 351, and not the production system302 (or any other system in a multisystem environment). Further, theprimary location does not change for the first subtype 351 a, as shownby the Type E setting primary location characteristic 350 beginning andending under the quality system 301 without ever changing for the firstsubtype 351 a.

The first subtype 351 a of Type E settings 351 can be useful for valuesthat affect the quality 301 system but do not affect or are not relevantfor the production system 302. For example, testing values, such as anaddress or location for test data inputs or a value indicating thenumber of times to run a test script, may be categorized as Type Esettings because they are used in the quality system 301 but have no usein the production system 302. Demo values that are useful in providing ademonstration (or tutorial or template) of the system are anotherexample.

The primary location of a second subtype 351 b of the Type E setting 351begins in the quality system 301 and then ends as a Type E setting 352in the production system 302. Thus, the primary location for the secondsubtype 351 b of Type E setting 351 is first the quality system 301 andis later changed to the production system 302. Once a second subtype's351 b primary location is changed to the setting 352 in the productionsystem 302, the primary location does not change again. In someembodiments, the primary location in this scenario may no longer beeditable.

This second subtype 351 b of the Type E setting 351 is analogous to theType B setting. This second subtype of Type E may be used, for example,when the first subtype 351 a of Type E 351 becomes useful in theproduction system 302, and so is given characteristics similar to thoseof Type B to facilitate the setting's use in the production system.

The primary location of a third subtype 351 c of the Type E setting 351begins in a quality system 301. Thereafter, the primary location changesto the production system 302 with the corresponding Type E setting 353.The primary location may then transfer between the setting 353 in theproduction system 302 and the setting 351 c in the quality system 301.

There is not a final primary location for the third subtype 351 c of theType E setting, because the third subtype's 351 c primary location maytransition between two systems in the multisystem environment. Theprimary location of the third subtype 351 c of the Type E 351 setting ismodifiable. This third subtype 351 c of the Type E setting 351 isanalogous to the Type C setting. The third subtype 351 c of Type Esetting 351 may be used, for example, when the first subtype 351 a ofType E 351 becomes useful in the production system 302, and so is givencharacteristics similar to those of Type C to facilitate the setting'suse in the production system but also allow for future testing in thequality system 301 of changes to the setting.

FIG. 4E illustrates a maintenance process 450 for Type E settings. Amaintenance process 450 a begins in the quality system 401. Themaintenance process 450 a occurs in the quality system 401 because thatsystem is the primary location for Type E settings. If Type E is dividedinto subtypes, this maintenance process 450 a corresponds to the firstsubtype 351 a of Type E setting 351.

In the quality system 401, a setting change may be initiated 451 for aType E setting. Initiating the setting change 451 may include detectingthat the setting is a Type E setting. It may also include retrieving thecurrent value of the setting or prompting the user to provide a newvalue. It may further include ensuring the setting may be changed at themoment, such as that there is no write lock on the setting or otherrestriction preventing a change.

The new value for the setting is provided and the setting is changed tothe new value at 452. The new value may come from user input, such asthrough a user interface, or from an external resource, such as adatabase, a batch update process, or a data feed from a data provider.

For the second subtype 351 b of Type E setting 351, the maintenanceprocess follows the maintenance process 420 for Type B, as shown in FIG.4B and described in Example 9—Type B Settings.

For the third subtype 351 c of Type E setting 351, the maintenanceprocess follows the maintenance process 430 for Type C, as shown in FIG.4C and described in Example 10—Type C Settings.

Example 13—System Setting Architecture

The interaction of settings between systems is illustrated in FIG. 5. Aquality system 510 may have two parts: an application 520 and storage540. Within the application 520 exists settings 530 for use by theapplication. The settings 530 may include a setting identifier and asetting value for each setting, such as a copy of settings 550 fromstorage 540. Alternatively, the settings 530 may include the settingvalue and all characteristics for each setting, such as a copy ofsettings 550 and the settings data 560 from storage 540, or somerelevant portion of the settings 550 and the settings data 560. Withinthe storage 540 exists settings 550 and settings data 560. The settingsdata 560 includes characteristics of the settings 550, such as the typeor the primary location. The settings 530 in the application 520 may beobtained from the settings 550 in the storage 540.

A production system 511 may have two parts: an application 521 andstorage 541. Within the application 521 exists settings 531 for use bythe application and settings lock data 532 for indicating the currentlock status of the settings. The settings lock data 532 may be for theentire collection of settings 531 or for each setting individually. Thesettings 531 may include a setting identifier and a setting value foreach setting, such as a copy of settings 551 from storage 541.Alternatively, the settings 531 may include the setting value and allcharacteristics for each setting, such as a copy of settings 551 and thesettings data 561 from storage 541, or some relevant portion of thesettings 551 and the settings data 561. Within the storage 541 existssettings 551 and settings data 561. The settings data 561 includescharacteristics of the settings 551, such as the type or primarylocation. The settings 531 in the application 521 may be obtained fromthe settings 551 in the storage 541.

All or part of the storage 540 of the quality system 510 may betransferred to the storage 541 of the production system 511. This may bedone as part of the export as described (e.g., in Examples 8-12) foreach type of setting. Further, this transfer may be done for allsettings or only for those settings approved for transfer. Approval fortransfer may be contingent on validation of a changed setting, or on thetype of setting. For example, Type A settings will never be transferredfrom the quality system 510 to the production system 511 (as describedin Example 8—Type A Settings).

Further, the settings in the applications 520, 521 of each system 510,511 may be transferred between each other as well. The settings 530 inthe application 520 of the quality system 510 may request access to thesettings 531 in the application 521 of the production system 511. Thisis accomplished through the settings lock data 532. If the setting islocked, the system 510 may not access the setting 531. In someembodiments, a locked setting 531 may still be read. A setting 531 maybe locked based on its type. For example, a Type A setting in theproduction system 511 may not be overwritten by the quality system 510.In another example, a Type C setting may be overwritten by the qualitysystem 510 based on the process described for Type C settings (Example10—Type C Settings). If a change is determined to be allowable, thechange may be made through the application 520, 521 or through thestorage 540, 541. Coordination of the change is managed through thesettings lock data 532.

In another embodiment, both systems 510, 511 may have settings lock data532. In such a scenario, the quality system 510 may have settings lockdata 532, which the production system 511 may access, similar to aspreviously described. This access may be based on the type of setting.

Example 14—Multiplicity of Systems

Descriptions herein for the functionality of the different setting typesuse two systems. However, these types may be used in multisystemenvironments with more than two systems. The functional relationship fora setting or a setting type may be between any two systems. For example,the functional relationship between the quality and production systemsfor a Type C (or any other type) setting may also be applied to adevelopment system and quality control system, or between a fourthsystem and the production system, and so on.

Further, the quality and production systems may also represent a set ofsystems. For example, “quality system” as used in the descriptions mayinclude two systems, such as a development and a quality control system,both relating to a production system as described. In this way, thedifferent setting types can be useful for sets of systems in amultisystem environment, and are not limited to a one-to-one systeminteraction.

Example 15—System Sessions

A system in the multisystem environment may have multiple sessions ofthe software active. For example, a system may have more than one useraccess the system and each user then has a separate session in thesoftware. Alternatively, each user may have a separate instance of thesoftware. These separate sessions or instances may access the samesettings on the system.

In another embodiment, the software on the system may be a multitenantapplication, having multiple tenants accessing the system, with eachtenant having multiple users. Each tenant may have a separate set ofsettings, thus the settings may differ from tenant to tenant.

If the session is reading the setting, this is generally an availableoption. If the session is attempting to change the setting, then thesession generally checks two things: the setting's primary location andif the setting is locked. Such a read/write lock may be implemented by aclash management system. If, based on the type of the setting, thesetting may be changed in that particular system, then the session canproceed to check if the setting is locked; otherwise, in some scenarios,the change may not proceed. The session then checks in the setting islocked, which will indicate if another session is currently accessingthe setting in the system. If so the setting is currently beingaccessed, such as being read or being changed, then the setting islocked and so cannot be changed. If the setting is not being accessed,then the change may proceed. Setting read/write locks may be implementedwith other or additional clash management techniques.

Example 16—System Transport Embodiment

The disclosed technologies may be implemented within a software platformfor configuration setting management during the lifecycle of thesoftware. This also facilitates treatment of the settings as part of thesoftware lifecycle. Examples of software platforms into which thedisclosed technologies may be integrated are S/4 HANA CE or S/4 HANA OP,both from SAP SE, of Walldorf, Germany.

The disclosed technologies may be integrated in a basis layer of thesoftware. This may include a definition of tables for the settings,including setting characteristics, and a maintenance view formaintaining the settings. Metadata may be used to control the status ofthe settings. The setting characteristics may be metadata. A table maybe a control table for the settings. Such a control table may controlthe status of the settings, and may implement at least part of theconfiguration management as disclosed. In one implementation, thecontrol table may be hosted on only one system in the multisystemenvironment. The control table may be accessible by other systems in themultisystem environment, and so function as a master control table.Clash management for individual settings may be implemented at themaster control table, or on each system.

Setting transfer between systems may be implemented as a transportmechanism. For example, transport may be implemented using ABAP standardtransport functionality. This may include disabling recording routinesfor the settings and implementing new routines. Such routines may writeto an export file setting information for another system based on thesetting's type or other characteristics. Then, the export file may bepushed to another system, where it is implemented and the settingchanges are made based on the export file. Thus, in this scenario,setting management is accomplished by controlling what is written toexport files of the system transport. For example, if a setting shouldnot be transferred, it is not written to the transport request; if asetting should be transferred, it is written to the transport requestwith the appropriate data and characteristics that should be transferredto the other system.

Example 17—Further Example Processes

FIG. 6A illustrates operations 601 executable within a system forconfiguration settings management in a multisystem environment. Thesystem may have a test system and a production system. The test systemalso has a setting, with a local copy of the setting at the test systemand another local copy of the setting at the production system. At 610,a system identifies the type for the setting based on the typeidentifier. At 620, a system maintains the setting based on the type.Maintaining includes, for a first type 622, making the primary locationthe production system, where the setting is initialized and editableonly at the production system. Maintaining includes, for a second type624, separating the setting between the test system and the productionsystem, such that the setting is not transferred or read between the twosystems and the first local copy is editable at the test system and thesecond local copy is editable at the production system. Maintainingincludes, for a third type 626, making the primary location the testsystem, where the setting is initialized and editable in the testsystem.

FIG. 6B illustrates computer-implemented instructions 602 forconfiguration settings management in a multisystem environment. At 630,a receiving system receives a request to edit a setting, the settingbeing associated with a type identifier, and the receiving system iseither a first system or a second system. At 640, a receiving systemdetermines a maintenance rule associated with the type identifier, wherethe maintenance rule determines how a value associated with the settingis maintained between the first system and the second system. Themaintenance rule may be, for a first type 642, to initialize andmaintain the setting in the second system. The maintenance rule may be,for a second type 644, to initialize and maintain the settingindependently in the first system and the second system. The maintenancerule may be, for a third type 646, to initialize and maintain thesetting in the first system without transferring the setting to thesecond system. At 650, the request to edit the value of the setting isallowed or denied in accordance with the determined maintenance rulebased on the determined type identifier and whether the receiving systemis the first system or the second system.

FIG. 6C illustrates a method 603 for configuration setting management ina multisystem environment. At 660, a system receives a request to changea setting in a first system in a plurality of systems. The first systemobtains setting data describing the setting at 670, which includes aprimary location identifier for identifying the primary system of thesetting. The first system compares its identifier to the primarylocation identifier for the setting at 680. At 690, if the first systemis the same as the primary location for the setting, then the firstsystem changes the setting according to the change request. Changing thesetting 690 may include changing the value of the setting or changing acharacteristic of the setting, such as the primary location, the type,or lock status of the setting.

Example 18—Computing Systems

FIG. 7 depicts a generalized example of a suitable computing system 700in which the described innovations may be implemented. The computingsystem 700 is not intended to suggest any limitation as to scope of useor functionality of the present disclosure, as the innovations may beimplemented in diverse general-purpose or special-purpose computingsystems.

With reference to FIG. 7, the computing system 700 includes one or moreprocessing units 710, 715 and memory 720, 725. In FIG. 7, this basicconfiguration 730 is included within a dashed line. The processing units710, 715 execute computer-executable instructions, such as forimplementing components of the processes of FIGS. 3A-E or FIGS. 4A-E, orthe systems of FIGS. 1A-B or FIG. 5, or the settings of FIGS. 2A-C. Aprocessing unit can be a general-purpose central processing unit (CPU),processor in an application-specific integrated circuit (ASIC), or anyother type of processor. In a multi-processing system, multipleprocessing units execute computer-executable instructions to increaseprocessing power. For example, FIG. 7 shows a central processing unit710 as well as a graphics processing unit or co-processing unit 715. Thetangible memory 720, 725 may be volatile memory (e.g., registers, cache,RAM), non-volatile memory (e.g., ROM, EEPROM, flash memory, etc.), orsome combination of the two, accessible by the processing unit(s) 710,715. The memory 720, 725 stores software 780 implementing one or moreinnovations described herein, in the form of computer-executableinstructions suitable for execution by the processing unit(s) 710, 715.The memory 720, 725, may also store settings or settingscharacteristics, such as data associated with settings in the qualitysystem in storage 540 or settings in the production system in storage541 as shown in FIG. 5.

A computing system 700 may have additional features. For example, thecomputing system 700 includes storage 740, one or more input devices750, one or more output devices 760, and one or more communicationconnections 770. An interconnection mechanism (not shown) such as a bus,controller, or network interconnects the components of the computingsystem 700. Typically, operating system software (not shown) provides anoperating environment for other software executing in the computingsystem 700, and coordinates activities of the components of thecomputing system 700.

The tangible storage 740 may be removable or non-removable, and includesmagnetic disks, magnetic tapes or cassettes, CD-ROMs, DVDs, or any othermedium which can be used to store information in a non-transitory wayand which can be accessed within the computing system 700. The storage740 stores instructions for the software 780 implementing one or moreinnovations described herein.

The input device(s) 750 may be a touch input device such as a keyboard,mouse, pen, or trackball, a voice input device, a scanning device, oranother device that provides input to the computing system 700. Theoutput device(s) 760 may be a display, printer, speaker, CD-writer, oranother device that provides output from the computing system 700.

The communication connection(s) 770 enable communication over acommunication medium to another computing entity. The communicationmedium conveys information such as computer-executable instructions,audio or video input or output, or other data in a modulated datasignal. A modulated data signal is a signal that has one or more of itscharacteristics set or changed in such a manner as to encode informationin the signal. By way of example, and not limitation, communicationmedia can use an electrical, optical, RF, or other carrier.

The innovations can be described in the general context ofcomputer-executable instructions, such as those included in programmodules, being executed in a computing system on a target real orvirtual processor. Generally, program modules or components includeroutines, programs, libraries, objects, classes, components, datastructures, etc. that perform particular tasks or implement particularabstract data types. The functionality of the program modules may becombined or split between program modules as desired in variousembodiments. Computer-executable instructions for program modules may beexecuted within a local or distributed computing system.

The terms “system” and “device” are used interchangeably herein. Unlessthe context clearly indicates otherwise, neither term implies anylimitation on a type of computing system or computing device. Ingeneral, a computing system or computing device can be local ordistributed, and can include any combination of special-purpose hardwareand/or general-purpose hardware with software implementing thefunctionality described herein.

In various examples described herein, a module (e.g., component orengine) can be “coded” to perform certain operations or provide certainfunctionality, indicating that computer-executable instructions for themodule can be executed to perform such operations, cause such operationsto be performed, or to otherwise provide such functionality. Althoughfunctionality described with respect to a software component, module, orengine can be carried out as a discrete software unit (e.g., program,function, class method), it need not be implemented as a discrete unit.That is, the functionality can be incorporated into a larger or moregeneral purpose program, such as one or more lines of code in a largeror general purpose program.

For the sake of presentation, the detailed description uses terms like“determine” and “use” to describe computer operations in a computingsystem. These terms are high-level abstractions for operations performedby a computer, and should not be confused with acts performed by a humanbeing. The actual computer operations corresponding to these terms varydepending on implementation.

Example 19—Cloud Computing Environment

FIG. 8 depicts an example cloud computing environment 800 in which thedescribed technologies can be implemented. The cloud computingenvironment 800 comprises cloud computing services 810. The cloudcomputing services 810 can comprise various types of cloud computingresources, such as computer servers, data storage repositories,networking resources, etc. The cloud computing services 810 can becentrally located (e.g., provided by a data center of a business ororganization) or distributed (e.g., provided by various computingresources located at different locations, such as different data centersand/or located in different cities or countries).

The cloud computing services 810 are utilized by various types ofcomputing devices (e.g., client computing devices), such as computingdevices 820, 822, and 824. For example, the computing devices (e.g.,820, 822, and 824) can be computers (e.g., desktop or laptop computers),mobile devices (e.g., tablet computers or smart phones), or other typesof computing devices. For example, the computing devices (e.g., 820,822, and 824) can utilize the cloud computing services 810 to performcomputing operations (e.g., data processing, data storage, and thelike).

Example 20—Implementations

Although the operations of some of the disclosed methods are describedin a particular, sequential order for convenient presentation, it shouldbe understood that this manner of description encompasses rearrangement,unless a particular ordering is required by specific language set forth.For example, operations described sequentially may in some cases berearranged or performed concurrently. Moreover, for the sake ofsimplicity, the attached figures may not show the various ways in whichthe disclosed methods can be used in conjunction with other methods.

Any of the disclosed methods can be implemented as computer-executableinstructions or a computer program product stored on one or morecomputer-readable storage media, such as tangible, non-transitorycomputer-readable storage media, and executed on a computing device(e.g., any available computing device, including smart phones or othermobile devices that include computing hardware). Tangiblecomputer-readable storage media are any available tangible media thatcan be accessed within a computing environment (e.g., one or moreoptical media discs such as DVD or CD, volatile memory components (suchas DRAM or SRAM), or nonvolatile memory components (such as flash memoryor hard drives)). By way of example, and with reference to FIG. 7,computer-readable storage media include memory 720 and 725, and storage740. The term computer-readable storage media does not include signalsand carrier waves. In addition, the term computer-readable storage mediadoes not include communication connections (e.g., 770).

Any of the computer-executable instructions for implementing thedisclosed techniques as well as any data created and used duringimplementation of the disclosed embodiments can be stored on one or morecomputer-readable storage media. The computer-executable instructionscan be part of, for example, a dedicated software application or asoftware application that is accessed or downloaded via a web browser orother software application (such as a remote computing application).Such software can be executed, for example, on a single local computer(e.g., any suitable commercially available computer) or in a networkenvironment (e.g., via the Internet, a wide-area network, a local-areanetwork, a client-server network (such as a cloud computing network), orother such network) using one or more network computers.

For clarity, only certain selected aspects of the software-basedimplementations are described. Other details that are well known in theart are omitted. For example, it should be understood that the disclosedtechnology is not limited to any specific computer language or program.For instance, the disclosed technology can be implemented by softwarewritten in C++, Java, Perl, JavaScript, Python, Ruby, ABAP, SQL, AdobeFlash, or any other suitable programming language, or, in some examples,markup languages such as html or XML, or combinations of suitableprogramming languages and markup languages. Likewise, the disclosedtechnology is not limited to any particular computer or type ofhardware. Certain details of suitable computers and hardware are wellknown and need not be set forth in detail in this disclosure.

Furthermore, any of the software-based embodiments (comprising, forexample, computer-executable instructions for causing a computer toperform any of the disclosed methods) can be uploaded, downloaded, orremotely accessed through a suitable communication means. Such suitablecommunication means include, for example, the Internet, the World WideWeb, an intranet, software applications, cable (including fiber opticcable), magnetic communications, electromagnetic communications(including RF, microwave, and infrared communications), electroniccommunications, or other such communication means.

The disclosed methods, apparatus, and systems should not be construed aslimiting in any way. Instead, the present disclosure is directed towardall novel and nonobvious features and aspects of the various disclosedembodiments, alone and in various combinations and sub combinations withone another. The disclosed methods, apparatus, and systems are notlimited to any specific aspect or feature or combination thereof, nor dothe disclosed embodiments require that any one or more specificadvantages be present or problems be solved.

The technologies from any example can be combined with the technologiesdescribed in any one or more of the other examples. In view of the manypossible embodiments to which the principles of the disclosed technologymay be applied, it should be recognized that the illustrated embodimentsare examples of the disclosed technology and should not be taken as alimitation on the scope of the disclosed technology. Rather, the scopeof the disclosed technology includes what is covered by the scope andspirit of the following claims.

What is claimed is:
 1. A system for configuration management in amultisystem environment, the system comprising: a test system having afirst local copy of a setting, wherein the setting has a type identifieridentifying a type of the setting and a primary location identifier; aproduction system having a second local copy of the setting; one or morememories; one or more processing units coupled to the one or morememories; and one or more non-transitory computer readable storage mediastoring instructions that, when loaded into the memories, cause the oneor more processing units to perform operations for managing the setting,comprising: identifying the type for the setting based on the typeidentifier; maintaining the setting based on the type, whereinmaintaining comprises: for a first type, making the primary location theproduction system, wherein the setting is initialized and editable onlyat the production system; for a second type, separating the settingbetween the test system and the production system, such that the settingis not transferred or read between the two systems and the first localcopy is editable at the test system and the second local copy iseditable at the production system; and for a third type, making theprimary location the test system, wherein the setting is initialized andeditable in the test system.
 2. The configuration management system ofclaim 1, wherein the maintaining further comprises: for a fourth type,making the primary location the test system when the production systemdoes not yet have the setting, wherein the setting is initialized andeditable in the test system; and transferring the setting to theproduction system and making the primary location the production system,wherein the setting is editable in the production system and onlyreadable by the test system.
 3. The configuration management system ofclaim 2, wherein the maintaining further comprises: for a fifth type,wherein the fifth type comprises the fourth type, further comprising:receiving a request from the test system for access to the setting;locking the setting in the production system; transferring the settingto the test system; making the primary location the test system,wherein, while the setting is locked in the production system, thesetting is editable in the test system and only readable in theproduction system; unlocking the setting in the production system;transferring the setting to the production system from the test system;and changing the primary location of the setting to the productionsystem.
 4. The configuration management system of claim 1, wherein thetype of the setting is editable.
 5. One or more non-transitorycomputer-readable storage media storing computer-executable instructionsfor causing a computing system to perform configuration managementbetween a first system and a second system, the processing comprising:receiving a request to edit a setting at a receiving system, the settingassociated with a type identifier, wherein the receiving system iseither the first system or the second system; determining a maintenancerule associated with the type identifier, the maintenance ruledetermining how a value associated with the setting is maintainedbetween the first system and the second system, the maintenance rulebeing selected from: for a first type, initialize and maintain thesetting in the second system; for a second type, initialize and maintainthe setting independently in the first system and the second system; fora third type, initialize and maintain the setting in the first systemwithout transferring the setting to the second system; and allowing ordenying the request to edit the value of the setting in accordance withthe determined maintenance rule based on the determined type identifierand whether the receiving system is the first system or the secondsystem.
 6. The one or more non-transitory computer-readable storagemedia of claim 5, wherein the maintenance rule is further selected from:for a fourth type, initialize and maintain the setting in the firstsystem while the second system does not have the setting, transfer thesetting to the second system, and maintain the setting in the secondsystem.
 7. The one or more non-transitory computer-readable storagemedia of claim 6, wherein the maintenance rule is further selected from:for a fifth type, the fifth type comprising the fourth type, furthercomprising: maintain the setting in the second system, transfer thesetting to the first system and lock the setting in the second system toprevent maintenance of the setting in the second system, transfer thesetting back to the second system from the first system, and unlock thesetting in the second system allowing maintenance in the second system.8. The one or more non-transitory computer-readable storage media ofclaim 5, wherein the type identifier of the setting is editable.
 9. Amethod for configuration management in a multisystem environment, themethod comprising: receiving a request to change a setting in a firstsystem of a plurality of systems; obtaining setting data describing thesetting, wherein the setting data comprises a primary locationidentifier for the setting; comparing an identifier of the first systemto the primary location identifier for the setting; and if the firstsystem is the same as the primary location for the setting, changing thesetting in the first system based on the change request.
 10. The methodfor configuration management of claim 9, further comprising: if thefirst system is not the same as the primary location for the setting,preventing the change to the setting in the first system.
 11. The methodfor configuration management of claim 9, further comprising: if thefirst system is not the same as the primary location for the setting,changing the setting in the first system based on the change request andpreventing the setting from being transferred to other systems in theplurality of systems.
 12. The method for configuration management ofclaim 9, further comprising: if the first system is the same as theprimary location for the setting, transferring the setting from thefirst system to a second system of the plurality of systems.
 13. Themethod for configuration management of claim 12, further comprising:after transferring the setting from the first system to the secondsystem, updating the primary location identifier of the setting to anidentifier of the second system.
 14. The method for configurationmanagement of claim 9, further comprising: if the first system is notthe same as the primary location for the setting, requesting access tothe setting from a second system, wherein the second system is theprimary location; if authorized by the setting data, changing theprimary location identifier to the identifier of the first system;changing the setting in the first system based on the change request;transferring the changed setting to the second system; and changing theprimary location identifier from the identifier of first system to anidentifier of the second system.
 15. The method for configurationmanagement of claim 14, further comprising: testing the changed settingin the first system, wherein testing continues until the changed settingis ready for transferring.
 16. The method for configuration managementof claim 9, wherein the setting data further comprises a type identifieridentifying a type of the setting.
 17. The method for configurationmanagement of claim 16, wherein the primary location is determinedaccording to the type.
 18. The method for configuration management ofclaim 16, wherein the editability of the primary location is determinedby the type.
 19. The method for configuration management of claim 16,wherein the type identifier is editable.
 20. The method forconfiguration management of claim 16, wherein the setting data furthercomprises a subtype identifier corresponding to the type identifier, foridentifying a subtype of the setting.